Evolving resistance to obesity in an insect

Warbrick-Smith, James; Behmer, Spencer T.; Lee, Kwang Pum; Raubenheimer, David; Simpson, Stephen J.

doi:10.1073/pnas.0605225103

Cited by 134 publications

(110 citation statements)

References 45 publications

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“…The negative correlation between weight and larval survival reported above could be the mechanism of selection for lower weight on a laboratory diet. This observation is consistent with observed rapid adaptation to laboratory diets seen in other systems (Warbrick-Smith et al 2006). However, also note that the canonical lab strains (Oregon R and Canton S, Figures 1 and 2) tended to have relatively high weights and pupal survival and low triglyceride content, hemolymph sugar concentration, and larval survival, which cautions against the assumption that metabolic regulation in standard lab strains is fully representative of the normal range of physiologies found in nature.…”

Section: Sources Of Phenotypic Variationsupporting

confidence: 58%

Genotype-by-Diet Interactions Drive Metabolic Phenotype Variation inDrosophila melanogaster

et al. 2010

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The rising prevalence of complex disease suggests that alterations to the human environment are increasing the proportion of individuals who exceed a threshold of liability. This might be due either to a global shift in the population mean of underlying contributing traits, or to increased variance of such underlying endophenotypes (such as body weight). To contrast these quantitative genetic mechanisms with respect to weight gain, we have quantified the effect of dietary perturbation on metabolic traits in 146 inbred lines of Drosophila melanogaster and show that genotype-by-diet interactions are pervasive. For several metabolic traits, genotype-by-diet interactions account for far more variance (between 12 and 17%) than diet alone (1-2%), and in some cases have as large an effect as genetics alone (11-23%). Substantial dew point effects were also observed. Larval foraging behavior was found to be a quantitative trait exhibiting significant genetic variation for path length (P ¼ 0.0004). Metabolic and fitness traits exhibited a complex correlation structure, and there was evidence of selection minimizing weight under laboratory conditions. In addition, a high fat diet significantly increases population variance in metabolic phenotypes, suggesting decreased robustness in the face of dietary perturbation. Changes in metabolic trait mean and variance in response to diet indicates that shifts in both population mean and variance in underlying traits could contribute to increases in complex disease.

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Section: Sources Of Phenotypic Variationsupporting

confidence: 58%

Genotype-by-Diet Interactions Drive Metabolic Phenotype Variation inDrosophila melanogaster

et al. 2010

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“…One mechanism that may have allowed such change could be selection for different utilization efficiency of carbohydrates [16]. Flies maintained on the protein-enriched diet have experienced relatively low access to easy accessible energy sources (carbohydrates).…”

Section: Discussionmentioning

confidence: 99%

“…Artificial selection experiments have also shown that the selection response is dependent on the nutritional environment, for instance in mice selected for larger body size [15]. Within insects, studies have used experimental evolution to study the impact of diet composition and it has been shown that rearing under alternative diet regimes for multiple generations results in genetically based changes in life-history traits [16,17].…”

Section: Introductionmentioning

confidence: 99%

Dietary protein content affects evolution for body size, body fat and viability in Drosophila melanogaster

et al. 2010

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The ability to use different food sources is likely to be under strong selection if organisms are faced with natural variation in macro-nutrient (protein, carbohydrate and lipid) availabilities. Here, we use experimental evolution to study how variable dietary protein content affects adult body composition and developmental success in Drosophila melanogaster. We reared flies on either a standard diet or a protein-enriched diet for 17 generations before testing them on both diet types. Flies from lines selected on protein-rich diet produced phenotypes with higher total body mass and relative lipid content when compared with those selected on a standard diet, irrespective of which of the two diets they were tested on. However, selection on protein-rich diet incurred a cost as flies reared on this diet had markedly lower developmental success in terms of egg-to-adult viability on both medium types, suggesting a possible trade-off between the traits investigated.

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“…An example of how postingestive responses can change over generations in response to a shift in the nutritional environment comes from the work of Warbrick- Smith et al (2006), who reared multiple lines of the diamondback moth, Plutella xylostella, for eight generations either on a carbohydrate-rich or a protein-rich diet. The carbohydrate-rich diet comprised either chemically defined artificial food or a high-starch mutant of the plant Arabidopsis.…”

Section: Evolving Postingestive Responsesmentioning

confidence: 99%

The nature of nutrition: a unifying framework

Simpson

Raubenheimer

2011

Aust. J. Zool.

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Abstract. We present a graphical approach, which we believe can help to integrate nutrition into the broader biological sciences, and introduce generality into the applied nutritional sciences. This 'Geometric Framework' takes account of the fact that animals need multiple nutrients in changing amounts and balance, and that nutrients come packaged in foods that are often hard to find, dangerous to subdue and costly to process. We then show how the Geometric Framework has been used to understand the links between nutrition and relevant aspects of the biology of individual animals. These aspects include the physiological mechanisms that direct the nutritional interactions of the animal with its environment, and the fitness consequences of these interactions. Having considered the implications of diet for individuals, we show that these effects can translate into the collective behaviour of groups and societies, and in turn ramify throughout food webs to influence the structure of ecosystems.

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Evolving resistance to obesity in an insect

Cited by 134 publications

References 45 publications

Genotype-by-Diet Interactions Drive Metabolic Phenotype Variation inDrosophila melanogaster

Genotype-by-Diet Interactions Drive Metabolic Phenotype Variation inDrosophila melanogaster

Dietary protein content affects evolution for body size, body fat and viability in Drosophila melanogaster

The nature of nutrition: a unifying framework

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